Closure device with rapidly eroding anchor

ABSTRACT

An anchor for use with a closure device includes a body being configured to move from a pre-deployed state to a deployed state. In the pre-deployed state, the body has a first width aspect relative to a direction of deployment and a second width aspect in the deployed state relative to the direction of deployment, the second width aspect being greater than the first width aspect and the body being formed from a rapidly eroding material configured to erode through dissolution within a body lumen.

CROSS-REFERENCE TO RELATED APPLICATIONS

This patent application is a continuation of U.S. patent application Ser. No. 12/684,569, now abandoned, entitled “Rapidly Eroding Anchor,” filed Jan. 8, 2010, which claims the benefit of and priority to U.S. Provisional Patent Application Ser. No. 61/143,751, entitled “Vessel Closure Devices and Methods,” filed Jan. 9, 2009, the disclosures of which are incorporated herein by reference in their entireties.

BACKGROUND

1. Technical Field

The present disclosure relates generally to medical devices and their methods of use. In particular, the present disclosure relates to vessel closure systems and devices and corresponding methods of use.

2. The Technology

Catheterization and interventional procedures, such as angioplasty or stenting, generally are performed by inserting a hollow needle through a patient's skin and tissue into the vascular system. A guidewire may be advanced through the needle and into the patient's blood vessel accessed by the needle. The needle is then removed, enabling an introducer sheath to be advanced over the guidewire into the vessel, e.g., in conjunction with or subsequent to a dilator.

A catheter or other device may then be advanced through a lumen of the introducer sheath and over the guidewire into a position for performing a medical procedure. Thus, the introducer sheath may facilitate introducing various devices into the vessel, while minimizing trauma to the vessel wall and/or minimizing blood loss during a procedure.

Upon completing the procedure, the devices and introducer sheath would be removed, leaving a puncture site in the vessel wall. Traditionally, external pressure would be applied to the puncture site until clotting and wound sealing occur. However, the patient must remain bedridden for a substantial period after clotting to ensure closure of the wound. This procedure may be time consuming and expensive, requiring as much as an hour of a physician's or nurse's time. It is also uncomfortable for the patient and requires that the patient remain immobilized in the operating room, catheter lab, or holding area. In addition, a risk of hematoma exists from bleeding before hemostasis occurs.

BRIEF SUMMARY

An anchor for using a closure device may include a body being configured to move from a pre-deployed state to a deployed state. In the pre-deployed state, the body has a first width aspect relative to a direction of deployment and a second width aspect in the deployed state relative to the direction of deployment, the second width aspect being greater than the first width aspect and wherein the body is formed from a rapidly eroding material configured to erode through dissolution within a body lumen.

A method of closing a puncture in a wall of a body lumen may include advancing an anchor in a deployment direction through the anchor, the anchor having a first width aspect relative to the deployment direction, deploying the anchor distally of the wall of the body lumen to cause the anchor to move to have a second width aspect relative to the deployment direction, the second width aspect being larger than the first width aspect, drawing the anchor distally into engagement with a distal side of the wall of the body lumen, and deploying a closure element into the wall of the body lumen, wherein the anchor is formed from a rapidly eroding material that dissolves in the body lumen in less than twelve hours.

A closure device system may include a delivery sheath, a rapidly eroding anchor at least partially disposed within the delivery sheath in an initial configuration, the closure member comprising one or more sugars, a suture element coupled to the closure member and disposed at least partially through the delivery sheath, and a pusher disposed at least partially within the delivery sheath and configured to deploy the anchor member from a distal end of the delivery sheath.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and are intended to provide further explanation of the invention claimed.

BRIEF DESCRIPTION OF THE DRAWINGS

To further clarify the above and other advantages and features of the present disclosure, a more particular description of the disclosure will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. It is appreciated that these drawings depict only illustrated embodiments of the disclosure and are therefore not to be considered limiting of its scope. The disclosure will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:

FIGS. 1A-1C illustrate a closure device in which a rapidly eroding anchor can be implemented according to one example;

FIGS. 1D-1F illustrate a method of closing a puncture in a wall of a body lumen in which a rapidly eroding anchor can be implemented;

FIGS. 2A-2E illustrate a closure device and a method for closing a puncture in a wall of a body lumen in which a rapidly eroding anchor can be implemented according to one example; and

FIG. 3 illustrates a closure device and a method for closing a puncture in a wall of a body lumen in which a rapidly eroding anchor can be implemented according to one example.

DETAILED DESCRIPTION

The present disclosure relates to devices, systems, and methods for closing an opening in a body lumen. For example, the present disclosure includes an anchor, such as an intra-arterial “foot,” comprising a rapidly eroding material. The anchor may be passed through an opening defined in a wall of a body lumen and deployed. The anchor can then be drawn proximally to draw the anchor into contact with a distal side of the body lumen wall. A closure element can then be deployed to close the puncture.

In at least one example, once deployed within a body lumen, the anchor may dissolve in less than a day or even less than an hour as desired. The rapid erosion of the anchor can allow the anchor to be left in place after the closure element has been deployed by obviating the need for removal of the anchor. By leaving the anchor in place until it dissolves, damage that may occur by drawing the anchor through the closed puncture and/or the deployed closure element can be reduced or eliminated.

In addition, the erosion time of the anchor may fall within the time frame of the action of an anti-thrombotic medication being used in conjunction with the treatment of a patient. Accordingly, the closure element of the present disclosure may reduce the risk of formation of intra-arterial clots associated with the closure of the body lumen opening.

Reference is now made to FIG. 1A, which illustrates a closure device 100 according to one example. As shown in FIG. 1A, the closure device 100 may include a delivery sheath 110 and a pusher 120 that are configured to cooperate to deploy an anchor 130, such as an intra-arterial foot, and a closure element 140, such as a plug, and a suture element 150. In at least one example, the delivery sheath 110 is configured to house the anchor 130 and the closure element 140 while the pusher 120 is configured to deploy the anchor 130 and/or the closure element 140 from the delivery sheath 110. The exemplary delivery sheath 110, pusher 120, anchor 130, and closure element 140 of FIG. 1A will be discussed in more detail with reference to FIG. 1B.

FIG. 1B illustrates an exploded view of the closure device 100. As shown in FIG. 1B, the delivery sheath 110 includes an outer housing 112 and a grip portion 114 while the pusher 120 includes a handle portion 122 and a shaft portion 124. An interior lumen 116 is defined in the outer housing 112 that is configured to receive the pusher 120 in such a manner as to allow the pusher 120 to be extended from and retracted within a distal end 112A of the outer housing 112. For example, the interior lumen 116 can include a first portion 116A configured to receive the shaft portion 124 of the pusher 120 while a second portion 116B of the interior lumen 116 can be configured to receive a distal end 124A of the shaft portion 124.

More specifically, the second portion 116B of the interior lumen 116 may have a larger width aspect than the width aspect of the first portion 116A. The width aspects of the first portion 116A and the second portion 116B can be the diameters thereof or other cross sectional profiles that are generally transverse to a center axis C of the delivery sheath 110. For ease of reference, the center axis C of the delivery sheath 110 will be referenced in describing the position and movement of the other components described herein. In the illustrated example, the interior lumen 116 may transition from the smaller diameter of the first portion 116A to a second larger diameter of the second portion 116B at a shoulder 118.

Such a configuration can allow the pusher 120 to translate axially relative to the delivery sheath 110 within a desired range of motion. In particular, the handle portion 122 can translate within the second portion 116B of the interior lumen 116 to advance the shaft portion 124 within the outer housing 112 to thereby move the distal end 124A of the shaft portion 124 relative to the distal end 112A of the outer housing 112. Interaction between the handle portion 122 and the shoulder 118 can help ensure the distal end 124A does not extend beyond a desired position within the outer housing 112.

In the illustrated example, the first portion 116A may also be configured to receive the anchor 130 and the closure element 140 proximally of the distal end 124A of the shaft portion 124. Accordingly, as the distal end 124A of the shaft portion 124 is advanced toward the distal end 112A of the outer housing 112, the distal end 124A of the shaft portion 124 can engage the anchor 130 and/or the closure element 140 to move the anchor 130 and/or the closure element 140 distally from the outer housing 112.

The anchor 130 can be configured to move from a pre-deployed state having a pre-deployed width aspect to a deployed state having a deployed width aspect. The deployed width aspect may be greater than the pre-deployed width aspect. The anchor 130 can have any configuration that allows for this. In the illustrated example, anchor 130 is configured to rotate or be rotated between the pre-deployed state and the deployed state. In other examples, the anchor 130 may be configured to unfold from a configuration have a pre-deployed width aspect to a deployed state having a greater width aspect. For example, one or more arms may be configured to unfold and fold about a plurality of pivot or hinge points.

As shown in FIG. 1B, the anchor 130 includes leg members 132, 134 that define a major axis 136 of the anchor 130. The anchor 130 can further include an eyelet 138 coupled to one or both of the leg members 132, 134. The eyelet 138 can be located at a position that causes the anchor 130 to rotate when a force acting initially parallel to the major axis 136 is exerted on the eyelet 138. Such a configuration can allow the anchor 130 to move from a state in which the major axis 136 is aligned with the central axis C to a state in which the major axis 136 is oriented more obliquely to the central axis C, such as generally perpendicular to the central axis C.

This rotation can be accomplished by applying a distally acting force on the anchor 130 to move the anchor 130 out of the outer housing 112 and then a proximally directed force to the anchor 130 by way of the eyelet 138. In at least one example, the distally acting force applied to the anchor 130 can be provided from the pusher 120 by way of the closure element 140 while the proximally directed force can be applied by way of the suture element 150. The anchor 130 can thus be used to position the closure device 100 for deployment of the closure element 140.

In one embodiment, the closure element 140 may be configured to close an opening in a lumen as well as at least partially obstruct a tissue tract leading from an external surface of the tissue to the lumen. The shape of the closure element 140 may be configured to be housed within the first portion 116A of the interior lumen 116. For example, the closure element 140 may conform to the shape of the interior lumen 116. In one embodiment, the closure element 140 may be cylindrical in shape prior to being deployed from the delivery sheath 110. Once deployed from the delivery sheath 110, the closure element 140 may be deformable to conform to any desired shape to close an opening in a body lumen and/or the tissue tract leading to the lumen opening.

As shown, the example pusher 120 can be coupled to the closure element 140 and/or anchor 130 by way of the suture element 150. In particular, the suture element 150 can loop through the anchor 130 such that the suture element 150 has two free ends that pass through or near the closure element 140, and extend proximally into or beyond the handle portion 122 of the pusher 120. In at least one example, the free ends of the suture element 150 pass through separate portions or channels of the closure element 140. In one embodiment, the pusher 120 can have a suture lumen 126 defined therein that extends through the shaft portion 124 and extends proximally to or even through the handle portion 122. The suture element 150 can be extended from the closure element 140 and into the pusher 120 by way of the suture lumen 126.

In one embodiment, the delivery sheath 110 may include a guidewire lumen 160 with a proximal guidewire port 162 therein near the proximal end 112B of the outer housing 112 and a distal guidewire port 164 near the distal end 112A of the outer housing 112. The guidewire lumen 160 may be at least partially integrated or entirely distinct from the interior lumen 116 of the delivery sheath 110. Accordingly, a guidewire can enter the proximal guidewire port 162, pass through the guidewire lumen 160, and exit the distal guidewire port 164. As a result, the example closure device 100 can advance over a guidewire and into position with a lumen opening as part of a method to close the lumen opening. One such method will now be discussed in more detail with reference to FIGS. 1C-1F.

Reference is now made to FIG. 1C, which illustrates a step in the process of deploying the anchor 130. As shown in FIG. 1C, the delivery sheath 110 can be positioned to move the distal end 112A of the outer housing 112 through a tract 170 defined in tissue 172 and into proximity with a lumen 174 and a puncture 176 defined in a lumen wall 178 in particular.

Thereafter, as shown in FIG. 1D, the pusher 120 can be manipulated as described above to cause the anchor 130 to be pushed out of the distal end 112A of the outer housing 112. For example, the pusher 120 may push the closure element 140 which may, in turn, push the anchor 130 distally relative to the outer housing 112, thereby deploying the anchor 130 from the distal end 112A of the outer housing 112. In one embodiment, once deployed, the anchor 130 may rotate or be rotated from a first orientation, in which the major axis 136 of the anchor 130 is at a small angle or generally parallel with the outer housing 112 and generally perpendicular to the lumen wall 178 as shown in FIG. 1C, to a second orientation in which the major axis 136 of the anchor 130 is generally parallel with the lumen 170 and at a greater angle or generally perpendicular to the delivery sheath 110 as shown in FIG. 1D.

In particular, as shown in FIG. 1D, once the anchor 130 is pushed from the distal end 112A of the outer housing 112, the anchor 130 may rotate or be rotated to the second orientation, such as by tension applied to by the suture element 150 to the anchor 130 by way of the eyelet 138. The anchor 130 can then be drawn in the proximal direction to secure the anchor 130 against a distal surface 178A of the lumen wall 178. The anchor 130 may comprise any of a number of different materials. In one example, the anchor 130 may comprise a bioabsorbable material. In a further embodiment, the anchor 130 may comprise a rapidly eroding material as disclosed in more detail herein.

As also shown in FIG. 1D, the anchor 130 can be used to stabilize tissue around the puncture 176 in order to facilitate closure of the puncture 176. In particular, once the anchor 130 is deployed, the anchor 130 may then be secured against a distal side 178A of the lumen wall 178 by pulling the suture element 150, which is coupled to the anchor 130, proximally. In one example, a suture lock (not shown) can be utilized to help maintain the tension in the suture element 150. Once the anchor 130 is secured against the distal side 178A of the lumen wall 178, the outer housing 112 may be advanced distally. In particular, the outer housing 112 can be advanced to exert a force against a proximal side 178B of the lumen wall 178. The combination of the forces exerted by the anchor 130 and the outer housing 112 on the lumen wall 178 may result in a compressive force on the tissue near the puncture 176. As a result, the puncture 176 may be compressed and/or located by the delivery sheath 110 and the outer housing 112 in particular. This may allow an adjustable sandwiching and location of the lumen opening by the combination of tension in the suture element 150 and compression created by the delivery sheath 110.

With the anchor 130 deployed, the pusher 120 may then deploy the closure element 140 within the puncture 176 and/or the tract 170 near a proximal side 178B of the lumen wall 178. In particular, as shown in FIG. 1E the pusher 120 can be advanced distally, the delivery sheath 110 can be drawn proximally, and/or some combination of such movements can be used to move the closure element 140 distally out of the outer housing 112 and into contact with the proximal side 178B of the lumen wall 178 adjacent the puncture 176.

In such a step, the lumen wall 178 is positioned between the anchor 130 and the closure element 140. Thus, the closure element 140 can be positioned to reduce or stop the flow of fluid out of the tract 170 by covering the puncture 176 and/or obstructing the tract 170.

In one embodiment, the pusher 120 remains in continuous contact with the closure element 140 throughout the deployment process. Such a configuration can allow the anchor 130 and/or closure element 140 to be deployed by advancing the pusher 120 in a single direction. By facilitating deployment of the anchor 130 and closure element 140 using one-way movement of the pusher 120, and by utilizing a single pusher 120, the closure device 100 may result in a quicker and easier deployment of the anchor 130 and/or closure element 140.

The engagement of the anchor 130 and the closure element 140 to the lumen wall 178 may be secured in any desired manner. In at least one example, the free ends of the suture element 150 may pass from the anchor 130 through the closure element 140. In such an example, a suture lock and/or a knot pusher can be used to advance a knot into proximity with the closure element 140 and tighten the knot to thereby maintain tension between the anchor 130 and the closure element 140. A suture cutter can then sever the suture element 150. A suture lock, a knot pusher, and/or a suture cutter can be advanced through a suture lumen 126 defined in the pusher 120 either before or after the delivery sheath 110 and the pusher 120 are withdrawn from the tract 170. As a result, the suture element anchor 130, closure element 140, and suture element 150 can remain in the tissue tract 170 as shown in FIG. 1F.

As previously introduced, the anchor 130 can be formed of a rapidly eroding material that allows the anchor 130 to be left in place within the lumen 174. The composition of the anchor 130 allows the anchor 130 to remain in position for a long enough period to enable the closure procedure and a short enough period to allow sufficient erosion of the anchor 130 while the patient is still under physician control or in the hospital. This time period can therefore be in a range of roughly between 30 minutes and 12 hours. The anchor 130 may be formed of a material that is strong enough to allow for secure anchoring of a closure element, such as the plug and/or other closure elements described below.

Further, the anchor 130 may be formed of a material that is biocompatible in an intravascular environment and non-thrombogenic. An anchor with these characteristics may be obtained by using a mechanism of dissolution rather than chemical degradation. Rapidly dissolving compounds that are suitable include, but are not limited to, sugars and sugar-derivatives like sugar-alcohols. Representative examples are sugars like glucose, fructose, lactose, maltose, and sugar alcohols like mannitol, sorbitol and isomalt. Strength can be added to the formulation by including a polymeric component, such as poly-vinylpyrrolidone, poly-ethyleneglycol, or a polysaccharide like starch, hydroxyethylstarch, dextran or dextran sulfate. Sugar alcohols such as mannitol, sorbitol, and isomalt have relatively low melting points, and form good solvents for the polysaccharides. This can facilitate manufacturing, since a simple melt process can be used. Various mixtures of these components are possible, resulting in potentially different anchor properties. Hydroxyethyl starch has a relatively low glass transition temperature, and so has a mannitol-sorbitol mixture. A solution of hydroxyethyl starch in mannitol-sorbitol, when solidified, may have a glass transition below body temperature, which will create a tough, but not brittle anchor. On the other end of the spectrum, a mixture of dextran with isomalt has a much higher glass transition, resulting in a very hard and strong anchor, but with higher brittleness. Since all these components are miscible, a wide range of properties can be achieved by mixing them in corresponding proportions to achieve the desired properties.

In one embodiment, the rapidly eroding material can be configured to be at least partially porous and/or micro-porous. Accordingly, one or more beneficial agents can be incorporated into at least one of the pores of the rapidly eroding material. For example, the beneficial agents may include anti-clotting agents, such as heparin, anti-inflammatory agents, and/or other beneficial agents. One method for producing a porous rapidly eroding material may include freeze drying the rapidly eroding material. In particular, in one example embodiment, acetic acid may be used as a solvent for freeze drying the rapidly eroding material. Polymers, such as PLGA, which are soluble in acetic acid, may be used as part of the freeze-drying process.

In a further embodiment, a micro-porous silicon may be used. In particular, the micro-porous silicon may be prepared with various degradation rates, including rapidly degrading forms. The micro-porous silicon may be sufficiently strong to be used in an anchor, such as a bioerodible foot, and/or may also have sufficient porosity to allow incorporation of beneficial agents. For example, in one embodiment, it may be desirable to incorporate a hydrophobic heparin derivative, such as benzalkonium heparin, into the porosity of the anchor because of its low solubility. The closure element 140 may comprise any number of different materials suitable for use as a plug.

FIG. 2A illustrates a closure device 200 in which an anchor 130′ similar to the anchor 130 described above may be implemented. In the illustrated example, the closure device 200 can include a delivery sheath 110′ having an outer housing 112′ and a grip portion 114′. An interior lumen 116′ is defined in the outer housing 112′ configured to house the anchor 130′. The closure device 200 further includes deployment assembly 210 that includes a garage sheath 220 configured to house an actuator member 230, which in turn can be configured to house a carrier tube 240, which in turn is configured to house a pusher 120′.

The pusher 120′ can be configured to translate axially within the carrier tube 240 to deploy the anchor 130′ from the closure device 200. A closure element 250 is configured to be positioned on the carrier tube 240. As will be discussed in more detail below, distal movement of the actuator member 230 relative to the carrier tube 240 may deploy the closure element 250.

In the illustrated example, the garage sheath 220 includes a housing portion 222 coupled to a plunger portion 224. The first plunger portion 224 can be positioned proximally of the grip portion 114′ of the delivery sheath 110. The actuator member 230 can include a housing portion 232 and a second plunger portion 234. The carrier tube 240 can also include a housing portion 242 and a third plunger portion 244. The pusher 120′ includes a handle portion 122′ and a shaft portion 124′.

As shown in FIG. 2B, the pusher 120′ can be used to deploy the anchor 130′ from the delivery sheath 110′ using a suture element 150′ in a similar manner as described above. Once the anchor 130′ is deployed, the first plunger portion 224 can be advanced proximally relative to the delivery sheath 110′ along with the second plunger portion 234 and the third plunger portion 244 to position the deployment assembly 210 in proximity with the lumen wall 178.

Thereafter, as shown in FIG. 2C, the first plunger portion 224 may be drawn proximally toward the second plunger portion 234 and the third plunger portion 244, the second plunger portion 234 and the third plunger portion 244 may be advanced distally, and/or some combination of those movements may be performed to expose the actuator member 230 and the carrier tube 240 from the garage sheath 220 while maintaining the carrier tube 240 in engagement with the lumen wall 178. In such an example, the delivery sheath 110′ can remain in place to maintain the lumen wall 178 between the delivery sheath 110′ and the anchor 130′.

As shown in FIG. 2D, the second plunger portion 234 can then be advanced distally relative to the third plunger portion 244 to expand and deploy the closure element 250. In particular, as shown in FIG. 2D, the carrier tube 240 includes ramped portions 246. As the second plunger portion 234 advances distally relative to the third plunger portion 244, the actuator member 230 pushes the closure element 250 over the ramped portions 246 of the carrier tube, thereby expanding the closure element 250. Thereafter, the closure device 200 can be removed and the suture element 250 cut as described above.

Continued advancement of the actuator member 230 distally relative to the carrier tube 240 moves tissue-engaging portions 252 of the closure element 250 into engagement with the lumen wall 178. Further distal movement of the actuator member 230 pushes the closure element 250 distally of the carrier tube 240. In at least one example, the closure element 250 can be formed of a resilient material having a trained or default state having a narrow diameter. The closure element 250 can be partially expanded onto the carrier tube 240 prior deployment. As the closure element 250 moves distally from the carrier tube 240, the closure element 250 can move toward the trained or default state, thereby closing the puncture 176.

As shown in FIG. 2E, once the closure element 250 is deployed, a plug material 260 may be injected near the lumen wall and within the tract 170. A suture element 150′ may be secured, such as by knotting, and then severed, thereby leaving the anchor 130′, closure element 250, and plug 260 in place while the remaining components of the closure device 200 are retracted. Thereafter, the rapidly eroding material of the anchor 130′ may then dissolve into the fluid flow within the lumen. In another example, the anchor maybe dissolved soon after the procedure allowing the suture element 250 to be removed and obviating the use of the plug material 260. In still further examples, the anchor 130′ may be let go down stream by slipping off the suture from the anchor, thus leaving behind only the closure element 250.

FIG. 3 illustrates a closure device 200′ configured for use as an over-the wire deployment that is similar to the closure device 200 shown in FIGS. 2A-2E. The closure device 250′ may be advanced over a guidewire 300. In the example shown in FIG. 3, the delivery sheath 110′ and garage sheath 220 of FIGS. 2A-2E have been omitted. In such an example, the anchor 130′ can be housed within the carrier tube 240 and pushed distally using a pusher 120′ translating therein. Thereafter, the closure device 200′ can deploy the anchor 130′ and the closure element 250 in a similar manner as described above with reference to FIGS. 2A-2E by advancing an actuator member 230 relative to a carrier tube 240.

Embodiments of the closure element, the delivery sheath, and the like may include a material made from any of a variety of known suitable biocompatible materials, such as a biocompatible shape memory material (SMM). For example, the SMM may be shaped in a manner that allows for a delivery orientation while within the tube set, but may automatically retain the memory shape of the component once deployed into the tissue to close the opening. SMMs have a shape memory effect in which they may be made to remember a particular shape. Once a shape has been remembered, the SMM may be bent out of shape or deformed and then returned to its original shape by unloading from strain or heating. Typically, SMMs may be shape memory alloys (SMA) comprised of metal alloys, or shape memory plastics (SMP) comprised of polymers. The materials may also be referred to as being superelastic.

Usually, an SMA may have an initial shape that may then be configured into a memory shape by heating the SMA and conforming the SMA into the desired memory shape. After the SMA is cooled, the desired memory shape may be retained. This allows for the SMA to be bent, straightened, twisted, compacted, and placed into various contortions by the application of requisite forces; however, after the forces are released, the SMA may be capable of returning to the memory shape. The main types of SMAs are as follows: copper-zinc-aluminum; copper-aluminum-nickel; nickel-titanium (NiTi) alloys known as nitinol; nickel-titanium platinum; nickel-titanium palladium; and cobalt-chromium-nickel alloys or cobalt-chromium-nickel-molybdenum alloys known as elgiloy alloys. The temperatures at which the SMA changes its crystallographic structure are characteristic of the alloy, and may be tuned by varying the elemental ratios or by the conditions of manufacture. This may be used to tune the component so that it reverts to the memory shape to close the arteriotomy when deployed at body temperature and when being released from the tube set.

For example, the primary material of a closure element and the like may be of a NiTi alloy that forms superelastic nitinol. In the present case, nitinol materials may be trained to remember a certain shape, retained within the tube set, and then deployed from the tube set so that the tines penetrate the tissue as it returns to its trained shape and closes the opening. Also, additional materials may be added to the nitinol depending on the desired characteristic. The alloy may be utilized having linear elastic properties or non-linear elastic properties.

An SMP is a shape-shifting plastic that may be fashioned into a closure element in accordance with the present disclosure. Also, it may be beneficial to include at least one layer of an SMA and at least one layer of an SMP to form a multilayered body; however, any appropriate combination of materials may be used to form a multilayered device. When an SMP encounters a temperature above the lowest melting point of the individual polymers, the blend makes a transition to a rubbery state. The elastic modulus may change more than two orders of magnitude across the transition temperature (Ttr). As such, an SMP may be formed into a desired shape of an endoprosthesis by heating it above the Ttr, fixing the SMP into the new shape, and cooling the material below Ttr. The SMP may then be arranged into a temporary shape by force and then resume the memory shape once the force has been released. Examples of SMPs include, but are not limited to, biodegradable polymers, such as oligo(ε-caprolactone)diol, oligo(ρ-dioxanone)diol, and non-biodegradable polymers such as, polynorborene, polyisoprene, styrene butadiene, polyurethane-based materials, vinyl acetate-polyester-based compounds, and others yet to be determined. As such, any SMP may be used in accordance with the present disclosure.

The closure element, the delivery sheath, and the like may have at least one layer made of an SMM or suitable superelastic material and other suitable layers may be compressed or restrained in its delivery configuration within the garage tube or inner lumen, and then deployed into the tissue so that it transforms to the trained shape. For example, the closure element may be set in a trained shape that has a relative small diameter. The closure element can then be expanded and moved into engagement with a body lumen wall adjacent a puncture. The closure element can then be allowed to return to the trained state to close the puncture.

Also, a closure element, the delivery sheath or other aspects or components of the closure system may be comprised of a variety of known suitable deformable materials, including stainless steel, silver, platinum, tantalum, palladium, nickel, titanium, nitinol, having tertiary materials (U.S. 2005/0038500, which is incorporated herein by reference, in its entirety), niobium-tantalum alloy optionally doped with a tertiary material (U.S. 2004/0158309, 2007/0276488, and 2008/0312740, which are each incorporated herein by reference, in their entireties) cobalt-chromium alloys, or other known biocompatible materials. Such biocompatible materials may include a suitable biocompatible polymer in addition to or in place of a suitable metal.

In one embodiment, the closure element, the delivery sheath, and the like may be made from a superelastic alloy such as nickel-titanium or nitinol, and includes a ternary element selected from the group of chemical elements consisting of iridium, platinum, gold, rhenium, tungsten, palladium, rhodium, tantalum, silver, ruthenium, or hafnium. The added ternary element improves the radiopacity of the nitinol.

In one embodiment, the closure element, the delivery sheath, and the like may be made at least in part of a high strength, low modulus metal alloy comprising Niobium, Tantalum, and at least one element selected from the group consisting of Zirconium, Tungsten, and Molybdenum.

In further embodiments, the closure element, the delivery sheath, and the like may be made from or be coated with a biocompatible polymer. Examples of such biocompatible polymeric materials may include hydrophilic polymer, hydrophobic polymer biodegradable polymers, bioabsorbable polymers, and monomers thereof. Examples of such polymers may include nylons, poly(alpha-hydroxy esters), polylactic acids, polylactides, poly-L-lactide, poly-DL-lactide, poly-L-lactide-co-DL-lactide, polyglycolic acids, polyglycolide, polylactic-co-glycolic acids, polyglycolide-co-lactide, polyglycolide-co-DL-lactide, polyglycolide-co-L-lactide, polyanhydrides, polyanhydride-co-imides, polyesters, polyorthoesters, polycaprolactones, polyesters, polyanydrides, polyphosphazenes, polyester amides, polyester urethanes, polycarbonates, polytrimethylene carbonates, polyglycolide-co-trimethylene carbonates, poly(PBA-carbonates), polyfumarates, polypropylene fumarate, poly(p-dioxanone), polyhydroxyalkanoates, polyamino acids, poly-L-tyrosines, poly(beta-hydroxybutyrate), polyhydroxybutyrate-hydroxyvaleric acids, polyethylenes, polypropylenes, polyaliphatics, polyvinylalcohols, polyvinylacetates, hydrophobichydrophilic copolymers, alkylvinylalcohol copolymers, ethylenevinylalcohol copolymers (EVAL), propylenevinylalcohol copolymers, polyvinylpyrrolidone (PVP), combinations thereof, polymers having monomers thereof, or the like.

The present disclosure may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the disclosure is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope. 

What is claimed is:
 1. A closure device for sealing an intravascular puncture site located in a wall in a blood vessel, the blood vessel defining a body lumen having a blood stream, the closure device comprising: a closure element made of biocompatible, hemostatic material; an anchor; and a tether extending through the anchor and the closure element, wherein the anchor comprises a body being configured to move from a pre-deployed state to a deployed state, wherein in the pre-deployed state the body has a first width aspect relative to a direction of deployment, and a second width aspect in the deployed state relative to the direction of deployment, the second width aspect being greater than the first width aspect, wherein the body is formed from a rapidly eroding material configured to erode through dissolution within a body lumen, the rapidly eroding material being a solid solution based on a sugar alcohol solvent and a solute, wherein the anchor initially has sufficient structural integrity to deploy through the puncture site and function as an anchor during placement of the closure element, and wherein the anchor erodes or dissolves more rapidly than the closure element so that, once the anchor is placed in the body lumen, it rapidly erodes or dissolves in the blood stream and leaves behind the closure element.
 2. The closure device of claim 1, wherein the body is configured to erode in less than twelve hours.
 3. The closure device of claim 1, wherein the body is configured to erode in less than one hour.
 4. The closure device of claim 1, wherein the body includes a major axis and wherein the body is configured to rotate in response to a force applied parallel to the major axis.
 5. The closure device of claim 1, wherein the sugar alcohol includes mannitol, sorbitol, or isomalt.
 6. The closure device of claim 1, wherein the body further includes at least one polymeric component.
 7. The closure device of claim 6, wherein the at least one polymeric component includes at least one of poly-vinylpyrrolidone, poly-ethyleneglycol, hydroxyethyl starch, polysaccharide, dextran or dextran sulfate.
 8. The closure device of claim 1, wherein the rapidly eroding material includes a plurality of pores.
 9. The closure device of claim 8, wherein at least one of the plurality of pores includes at least one beneficial agent.
 10. The closure device of claim 1, wherein the anchor includes at least one of poly-vinyl pyrrolidone, hyaluronic acid, dextran, hydrogel, heparin, and benzalkonium heparin.
 11. The closure device of claim 1, wherein the anchor is formed using a freeze-drying process.
 12. The closure device of claim 1, wherein the solid solution is a solid solution of hydroxyethyl starch in mannitol-sorbitol.
 13. The closure device of claim 1, wherein the body includes an eyelet extending through the body. 